WO2015050244A1 - Method and device for filling of liquid material - Google Patents
Method and device for filling of liquid material Download PDFInfo
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- WO2015050244A1 WO2015050244A1 PCT/JP2014/076544 JP2014076544W WO2015050244A1 WO 2015050244 A1 WO2015050244 A1 WO 2015050244A1 JP 2014076544 W JP2014076544 W JP 2014076544W WO 2015050244 A1 WO2015050244 A1 WO 2015050244A1
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- chamber
- liquid material
- pressure
- storage container
- filling
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B41—PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
- B41J—TYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
- B41J2/00—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed
- B41J2/005—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by bringing liquid or particles selectively into contact with a printing material
- B41J2/01—Ink jet
- B41J2/17—Ink jet characterised by ink handling
- B41J2/175—Ink supply systems ; Circuit parts therefor
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B41—PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
- B41J—TYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
- B41J2/00—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed
- B41J2/005—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by bringing liquid or particles selectively into contact with a printing material
- B41J2/01—Ink jet
- B41J2/17—Ink jet characterised by ink handling
- B41J2/175—Ink supply systems ; Circuit parts therefor
- B41J2/17503—Ink cartridges
- B41J2/17506—Refilling of the cartridge
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B41—PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
- B41J—TYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
- B41J2/00—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed
- B41J2/005—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by bringing liquid or particles selectively into contact with a printing material
- B41J2/01—Ink jet
- B41J2/17—Ink jet characterised by ink handling
- B41J2/175—Ink supply systems ; Circuit parts therefor
- B41J2/17503—Ink cartridges
- B41J2/17513—Inner structure
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B41—PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
- B41J—TYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
- B41J2/00—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed
- B41J2/005—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by bringing liquid or particles selectively into contact with a printing material
- B41J2/01—Ink jet
- B41J2/17—Ink jet characterised by ink handling
- B41J2/175—Ink supply systems ; Circuit parts therefor
- B41J2/17503—Ink cartridges
- B41J2/17556—Means for regulating the pressure in the cartridge
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B41—PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
- B41J—TYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
- B41J2/00—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed
- B41J2/005—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by bringing liquid or particles selectively into contact with a printing material
- B41J2/01—Ink jet
- B41J2/17—Ink jet characterised by ink handling
- B41J2/175—Ink supply systems ; Circuit parts therefor
- B41J2/17503—Ink cartridges
- B41J2/17559—Cartridge manufacturing
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B41—PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
- B41J—TYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
- B41J2/00—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed
- B41J2/005—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by bringing liquid or particles selectively into contact with a printing material
- B41J2/01—Ink jet
- B41J2/17—Ink jet characterised by ink handling
- B41J2/19—Ink jet characterised by ink handling for removing air bubbles
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B41—PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
- B41J—TYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
- B41J29/00—Details of, or accessories for, typewriters or selective printing mechanisms not otherwise provided for
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B41—PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
- B41J—TYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
- B41J29/00—Details of, or accessories for, typewriters or selective printing mechanisms not otherwise provided for
- B41J29/38—Drives, motors, controls or automatic cut-off devices for the entire printing mechanism
- B41J29/393—Devices for controlling or analysing the entire machine ; Controlling or analysing mechanical parameters involving printing of test patterns
Definitions
- the present invention relates to a liquid material filling apparatus and method for filling a liquid material discharge apparatus with a liquid material.
- the present invention relates to a liquid material filling apparatus and method for filling a liquid material without leaving bubbles in a flow path not filled with the liquid material when starting to use the liquid material discharge apparatus.
- a shaft body that rotates or moves back and forth is disposed in a flow path from a supply port to which the liquid material is supplied to a discharge port to which the liquid material is discharged.
- a device that discharges a liquid material from a discharge port is known (for example, Patent Document 1).
- the liquid material stored in the syringe is introduced into a flow path formed in the distribution device housing through the hole, and the liquid material is discharged from the nozzle by the advance movement of the shaft. It is what is done.
- the shaft is inserted into the flow hole, and the flow path is formed by a gap between the shafts inserted into the flow holes.
- the shaft is configured so as not to leak toward the control mechanism that is the drive source of the shaft by the seal ring, and thus the liquid material stored in the syringe flows to the discharge port of the nozzle. It is configured so that all the paths are filled with liquid material.
- the discharge device having such a configuration causes variation in the amount of liquid material discharged by the device when bubbles are present in the flow path. Further, if bubbles are mixed at the start of use, it is difficult to eliminate them, which has been a factor that impedes accurate discharge. Specifically, bubbles are discharged during discharge, and the liquid material is not discharged, or a discharge failure such as no formation of liquid droplets occurs even when the liquid material is discharged. For this reason, conventionally, a storage container (syringe) filled with a liquid material has been subjected to centrifugal defoaming or vacuum defoaming and then attached to the discharge device main body.
- JP 2004-322099 A Japanese Patent Laid-Open No. 2006-248083
- Patent Document 2 makes it possible to degas bubbles in the ink storage unit.
- new bubbles are mixed in the flow path that connects the ink storage unit and the cap unit. It can happen.
- a three-way valve or a flow rate adjusting valve between the ink storage part and the cap part has a bent part or a step part, there is a possibility that air bubbles may remain there.
- air bubbles may be generated when ink is sucked into the air bypass that occurs when the three-way valve is switched (see paragraph [0039] in the same document), and the ink containing the air bubbles flows after the ink is discharged to the ink pan. May remain inside.
- an object of the present invention is to provide a liquid material filling apparatus and method that can eliminate bubbles remaining over the entire length of the flow path from the liquid material reservoir to the discharge port.
- a liquid material filling apparatus includes a chamber having an airtight structure, a pressure adjusting unit that regulates the pressure in the chamber, and a control device, and the liquid material filling apparatus fills the internal flow path of the discharge device with the liquid material.
- the discharge device includes a liquid storage container having an outlet and a connector communicated with the discharge port, and the pressure adjusting unit includes a negative pressure supply source, a chamber communication pipe communicating with the chamber, and the liquid storage container.
- a discharge device communication pipe that communicates with the connector, an on-off valve A that communicates or blocks the chamber communication tube and the gas supply port, an on-off valve B that communicates or blocks the chamber communication tube and the discharge device communication pipe, and a discharge device And an on-off valve C for connecting or shutting off the communication pipe and the gas supply port, and a pressure gauge, and the control device communicates the negative pressure supply source with the chamber communication pipe and the discharge apparatus communication pipe.
- Pressure reducing means for reducing the space in the bar and above the storage container to a vacuum or a low pressure close to vacuum, and maintaining the space in the chamber and above the storage container at a low pressure for a certain period of time, bubbles in the liquid material
- Degassing means for degassing filling means for filling the discharge device with the liquid material in the storage container at a higher pressure than in the chamber by communicating the gas above the space above the storage container with the gas supply port,
- a filling stopping means for bringing the space above the storage container into communication with the inside of the chamber to achieve a pressure equilibrium state, and a pressure releasing means for connecting the space in the chamber and above the storage container with the gas supply port are provided.
- a switching valve for switching between a first position for communicating the chamber communication pipe and the negative pressure supply source and a second position for communicating the chamber communication pipe and the gas supply port is further provided.
- the control device sets the switching valve to the first position in the decompression means, and sets the switching valve to the second position in the pressure release means, and more preferably further includes a chamber.
- a first flow control valve provided in a flow path that communicates the communication pipe and the gas supply port; and a second flow control valve provided in a flow path that communicates the discharge apparatus communication pipe and the gas supply port. More preferably, the maximum flow rate of the first flow control valve is set to be three times or more the maximum flow rate of the second flow control valve.
- the liquid material filling device may further include a sensor that transmits a liquid detection signal to the control device.
- the liquid material filling method of the present invention is a method of filling an internal flow path of a discharge device installed in a chamber with a liquid material, wherein the discharge device includes an outlet communicated with a discharge port and a pipe to which negative pressure is supplied.
- the discharge device includes an outlet communicated with a discharge port and a pipe to which negative pressure is supplied.
- Including a liquid storage container with a connected connector decompressing the space in the chamber and above the storage container to a vacuum or a low pressure close to vacuum, reducing the space in the chamber and above the storage container for a certain period of time
- a degassing step for degassing bubbles in the liquid material while maintaining the pressure state, and the space above the storage container is connected to the gas supply port so that the gas flows in to a higher pressure than in the chamber.
- the filling process of filling the liquid material in the discharge device after detecting that the liquid droplet flows out from the discharge port, the space above the storage container is immediately communicated with the inside of the chamber to be in a pressure equilibrium state, Filling stopping step of stopping the filling of the body material, and characterized by having a pressure release step of the space above the chamber and the reservoir in communication with the gas supply port flows of gas.
- the liquid material filling method may be characterized in that, in the decompression step, the air in the chamber and the storage container is gently discharged by adjusting the flow rate control valve over time.
- the gas in the filling step, the gas is gently introduced into the space above the storage container while adjusting the flow rate control valve over time, and in the pressure release step, the flow rate control valve
- the gas may gradually flow into the space above the storage container while adjusting the time, and preferably, in the pressure release step, the maximum flow rate of the flow control valve is It is characterized by being set to 3 times or more of the maximum flow rate of the flow rate control valve in the filling step.
- the discharge device may be a discharge device in which a rod operates in a liquid chamber communicating with a discharge port.
- the liquid material filling apparatus 1 of the present invention includes a chamber 10, a pressure adjustment unit 70, and a control device 100 as main components.
- the discharge device 50 is installed in the chamber 10 having an airtight structure, and a filling process is performed.
- the pressure adjusting unit 70 adjusts the pressure of the storage container 51 of the chamber 10 and the discharge device 50, and the operation is controlled by the control device 100.
- the chamber 10 includes a door 11 fixed by a hinge, a handle 12, locking members 13 to 14, and an airtight member 15.
- the door 11 is opened and closed by grasping the handle 12.
- the chamber 11 can be hermetically sealed by fixing the door 11 with the locking tool A13 and the locking tool B14 in a state where the door 11 is closed and the airtight member 15 provided in a frame shape is pressed.
- a control device 100 and a pressure adjusting unit 70 are installed in a rectangular parallelepiped casing at the top of the chamber 10.
- a negative pressure gauge A87 and a negative pressure gauge B88 are arranged on the front face of the housing, and can be visually recognized from the front face.
- the pressure adjusting unit 70 includes a negative pressure supply source 71, flow rate control valves 80 to 82, on-off valves 83 to 85, a switching valve 86, and negative pressure gauges 87 to 88.
- the negative pressure supply source 71 supplies a predetermined negative pressure, and can be configured, for example, by combining a vacuum pump with a pressure reducing valve.
- the switching valve 86 switches between a first position where the negative pressure supply source 71 and the on-off valve A83 communicate with each other and a second position where the on-off valve A83 and the gas supply port 92 communicate with each other via the flow rate control valve C82.
- One end of the pipe A90 inserted through the chamber 10 is open to the chamber space.
- One end of the pipe B91 inserted through the chamber 10 communicates with the lower end outlet of the storage container 51.
- the pipe A 90 and the pipe B 91 communicate with the gas supply ports 92 and 93 and the negative pressure source 71 through the flow control valves 80 to 82, the on-off valves 83 to 85, and the switching valve 86.
- the gas supply port communicates with the atmosphere to supply atmospheric gas.
- the gas supply port communicates with an inert gas supply source to supply the inert gas.
- the control device 100 is electrically connected to each element of the droplet detection sensor 61 and the pressure adjusting unit 70 as shown in FIG.
- the control device 100 includes an arithmetic device and a storage device, and automatically controls the operations of the switching valve 86 and the on-off valves 83 to 85 based on signals from the droplet detection sensor 61 and the negative pressure gauges 87 to 88 in a filling process described later. To do.
- movement of each element of the pressure adjustment part 70 by time you may provide the timer implement
- the droplet detection sensor 61 detects a droplet (or thread-like liquid) discharged from the discharge port 53 of the discharge device 50 and transmits a detection signal to the control device 100.
- a measuring device for measuring the droplets may be provided in the tray 62 so that the discharge of the droplets can be detected by a change in the weight of the tray 62.
- FIG. 4 is a cross-sectional side view of an essential part showing the configuration of the ejection device 50.
- the storage container 51 and the discharge device main body 52 are connected to each other via a liquid feeding member 56 provided with a flow path therein.
- An electromagnetic valve 57 is fixed on one side surface of the discharge device main body 52.
- the tip of a rod 55 extending in the vertical direction is disposed in the liquid chamber 54 communicating with the discharge port 53.
- the rod 55 reciprocates in the liquid chamber 54 by a rod drive source made of, for example, a piezo element.
- the storage container 51 has an outlet at the lower end and an opening at the upper end.
- An air tube is connected to a lid member (connector) that covers the opening of the storage container 51 and communicates with an air supply port of the air pressure supply 58.
- the controller 59 controls the operation of the solenoid valve 57 and the air pressure supply 58.
- the discharge device 50 is installed in the chamber 10, the air pressure supply 58 and the controller 59 are disconnected.
- the rod 55 is fixed at the raised position so that the rod 55 does not block the flow path connecting the liquid chamber 54 and the discharge port 53. That is, the discharge device 50 in a state where the discharge port 53 and the outlet of the liquid storage container 51 communicate with each other is installed in the chamber 10.
- the discharge device 50 includes a work table on which an application target is placed, an XYZ direction moving device that relatively moves the liquid fixed amount discharge device and the work table, and a control unit that controls the operation of the XYZ direction moving device. It is mounted on a coating device and used.
- the discharge device 50 shown in FIG. 4 is merely an example, and the present invention can be applied to any discharge device in which a rod operates in a liquid chamber communicating with a discharge port.
- a jet type that causes the valve body to collide with the valve seat provided at the end of the flow path communicating with the nozzle or stops just before the valve body collides with the valve seat and causes the liquid material to fly and discharge from the nozzle tip.
- the present invention also relates to a discharge device, a plunger type that moves a desired amount of a plunger that slides in close contact with the inner surface of a storage container having a nozzle at the tip, and a screw type discharge device that discharges a liquid material by rotating a screw. Applicable.
- ⁇ Filling process> (Preparation process: installation of the discharge device, etc.) The worker performs the following work as a preparation process.
- the discharge device 50 is attached to the holder 60 in the chamber 10.
- the tube B91 is connected to a lid member that covers the opening of the storage container 51 that stores the liquid material, and a closed space is created above the storage container 51.
- a tray 62 is installed below the discharge port 53 of the discharge device 50.
- the vertical line extending downward from the discharge port 53 of the discharge device 50 and the detection range of the droplet detection sensor 61 overlap.
- the control device 100 sets the switching valve 86 to the first position where the negative pressure supply source 71 and the on-off valve A83 communicate with each other, opens the on-off valve A83 and the on-off valve B84, and closes the on-off valve C85.
- the negative pressure supply source 71 communicates with the chamber 10 via the pipe A90 and communicates with the storage container 51 via the pipe B91. Therefore, the negative pressure from the negative pressure supply source 71 reduces the pressure in the chamber 10 and the pressure of the gas existing above the storage container 51.
- the flow rate control valve A80 is adjusted over time by the control device 100 so that the air in the chamber 10 and the storage container 51 is not exhausted rapidly. If a sudden pressure change occurs in the flow path in the discharge device 50 and the storage container 51, there is a risk of bubbles being mixed. In particular, if the liquid material in the storage container 51 is violated, the risk of mixing bubbles is considerably increased. It is.
- the control device 100 closes the on-off valve B84 after a certain period of time and blocks communication between the pipe A90 and the pipe B91. Thereby, the communication between the chamber 10 and the space above the storage container 51 is blocked. Subsequently, the control device 100 closes the flow control valve B81 and then opens the on-off valve C85. At this time, since the flow control valve B81 is closed, the indicated value of the negative pressure gauge B88 does not change. Subsequently, the control device 100 gradually opens the flow rate control valve B81. As a result, atmospheric gas flows from the gas supply port 93 into the space above the storage container 51 via the on-off valve C85. At this time, it is preferable to adjust the degree of opening of the flow control valve B81 by the control device 100 so that the liquid material in the storage container 50 does not suddenly flow into the internal flow path of the device main body 52.
- the pressure in the storage container 51 increases, and the indicated value of the negative pressure gauge B88 also increases.
- the atmospheric gas inflow (pressure increase) into the storage container 51 is performed until the negative pressure gauge B88 indicates a desired pressure value. Since the communication between the flow path B91 and the flow path A90 is blocked by the liquid material in the storage container 51, the indicated value of the negative pressure gauge A87 does not increase.
- the difference between the indicated value of the negative pressure gauge A87 and the indicated value of the negative pressure gauge B88 is the differential pressure between the storage container 51 and the internal flow path of the apparatus main body 52. This differential pressure becomes a propulsion pressure for feeding the liquid material in the storage container 51 into the internal flow path of the discharge device.
- the negative pressure in the chamber 10 is, for example, ⁇ 60 to ⁇ 100 kPa, and the differential pressure between the negative pressure gauge A and the negative pressure gauge B is, for example, several tens of kPa to several hundred kPa.
- the method of opening the flow control valve B81 after the control device 100 opens the on-off valve C85 has been described. May be.
- the control device 100 opens the on-off valve B84 and connects the pipe A90 and the pipe B91. Thereby, the pressure difference between the pressure in the storage container 51 and the chamber 10 is eliminated, and the inflow of the liquid material from the storage container 51 to the internal flow path of the apparatus main body 52 is stopped. At this time, the indicated values of the negative pressure gauge A87 and the negative pressure gauge B88 are equal (pressure equilibrium state).
- the control device 100 sets the switching valve 86 to the second position, and causes the on-off valve A83 and the flow rate control valve C82 to communicate with each other. At this time, the on-off valve A83 and the flow rate control valve C82 are in a closed state, and the on-off valve B84 is in an open state. Subsequently, the control device 100 opens the on-off valve A83 and gradually opens the flow rate control valve C82. As a result, atmospheric gas flows from the gas supply port 92 into the chamber 10 through the pipe A90 and flows into the upper space of the storage container 51 through the pipe B91. The pressure in the chamber 10 and the storage container 51 rises and becomes equal to the atmospheric pressure.
- atmospheric gas may flow into the upper space of the chamber 10 and the storage container 51 from the gas supply port 93. That is, the control device 100 sets the on-off valve A83, the on-off valve C85 and the flow rate control valve B81 in the closed state, and the on-off valve B84 in the open state. May be. Also here, the opening / closing valve C85 may be opened after the opening degree of the flow control valve B81 is set in advance by the control device 100. When the negative pressure in the chamber is released via the gas supply port 93, the switching valve 86 is not necessary, and the flow control valve A80 and the on-off valve A83 can be directly connected.
- the latter has a significantly larger amount of inflow. May be good. That is, in the configuration in which the switching valve 86 is provided, atmospheric gas flows from the gas supply port 92 through a large flow rate valve, and atmospheric gas flows from the gas supply port 93 through a small flow rate valve. Therefore, the negative pressure in the chamber can be quickly released in the fifth step.
- the maximum flow rate of the flow control valve C82 can be set to 3 times or more (preferably 5 times or more, more preferably 10 times or more) of the flow control valve B81.
- the liquid material filling apparatus 1 since the liquid material is filled in a vacuum state in which the atmosphere does not remain or in a substantially vacuum state, the liquid material filling device 1 remains in every corner of the flow path from the storage container to the discharge port. Liquid material without bubbles spreads. Further, since the discharge device itself is in a vacuum state in the chamber, there is no possibility that gas flows from the discharge port into the internal flow path of the discharge device. According to the present invention, since bubbles do not remain in the flow path from the storage container to the discharge port, an advantageous effect is achieved that the discharge amount is stable and discharge failure does not occur. Further, since there is no liquid dripping or no dripping from the discharge port due to residual bubbles, the liquid can be discharged cleanly.
- the present invention is particularly effective for a mechanical discharge device in which a tip end portion of a work shaft (rod) is disposed in a liquid chamber communicating with a discharge port.
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- Manufacturing & Machinery (AREA)
- Coating Apparatus (AREA)
- Basic Packing Technique (AREA)
- Filling Of Jars Or Cans And Processes For Cleaning And Sealing Jars (AREA)
- Application Of Or Painting With Fluid Materials (AREA)
- Ink Jet (AREA)
Abstract
Description
特許文献1の図1に開示される装置は、シリンジに貯留される液体材料が、穴を介して分配装置ハウジングに形成された流路に導入され、シャフトの進出移動によりノズルから液体材料が吐出されるものである。ここで、シャフトは、流動穴に挿入されており、流路は流動穴に挿入されたシャフトの間隙で形成される。また、シャフトは、シールリングでシャフトの駆動源である制御機構に向かって漏出しないように構成されており、従って、シリンジ内に貯留された液体材料はノズルの吐出口に至る分配装置内の流路がすべて液体材料で満たされるよう構成される。 As a device for discharging a liquid material, a shaft body that rotates or moves back and forth is disposed in a flow path from a supply port to which the liquid material is supplied to a discharge port to which the liquid material is discharged. A device that discharges a liquid material from a discharge port is known (for example, Patent Document 1).
In the device disclosed in FIG. 1 of Patent Document 1, the liquid material stored in the syringe is introduced into a flow path formed in the distribution device housing through the hole, and the liquid material is discharged from the nozzle by the advance movement of the shaft. It is what is done. Here, the shaft is inserted into the flow hole, and the flow path is formed by a gap between the shafts inserted into the flow holes. In addition, the shaft is configured so as not to leak toward the control mechanism that is the drive source of the shaft by the seal ring, and thus the liquid material stored in the syringe flows to the discharge port of the nozzle. It is configured so that all the paths are filled with liquid material.
上記液体材料充填装置において、好ましくは、さらに、チャンバー連通管と負圧供給源とを連通する第1の位置およびチャンバー連通管とガス供給口とを連通する第2の位置を切り換える切換弁とを備え、前記制御装置が、前記減圧手段において切換弁を第1の位置とすること、並びに、前記圧力開放手段において切換弁を第2の位置とすることを特徴とし、より好ましくは、さらに、チャンバー連通管とガス供給口とを連通する流路に設けられた第1の流量制御弁と、吐出装置連通管とガス供給口とを連通する流路に設けられた第2の流量制御弁とを備えることを特徴とし、さらに好ましくは第1の流量制御弁の最大流量が、第2の流量制御弁の最大流量の3倍以上に設定されることを特徴とする。
上記液体材料充填装置において、さらに、前記制御装置に液体検出信号を送信するセンサを備えることを特徴としてもよい。 A liquid material filling apparatus according to the present invention includes a chamber having an airtight structure, a pressure adjusting unit that regulates the pressure in the chamber, and a control device, and the liquid material filling apparatus fills the internal flow path of the discharge device with the liquid material. The discharge device includes a liquid storage container having an outlet and a connector communicated with the discharge port, and the pressure adjusting unit includes a negative pressure supply source, a chamber communication pipe communicating with the chamber, and the liquid storage container. A discharge device communication pipe that communicates with the connector, an on-off valve A that communicates or blocks the chamber communication tube and the gas supply port, an on-off valve B that communicates or blocks the chamber communication tube and the discharge device communication pipe, and a discharge device And an on-off valve C for connecting or shutting off the communication pipe and the gas supply port, and a pressure gauge, and the control device communicates the negative pressure supply source with the chamber communication pipe and the discharge apparatus communication pipe. Pressure reducing means for reducing the space in the bar and above the storage container to a vacuum or a low pressure close to vacuum, and maintaining the space in the chamber and above the storage container at a low pressure for a certain period of time, bubbles in the liquid material Degassing means for degassing, filling means for filling the discharge device with the liquid material in the storage container at a higher pressure than in the chamber by communicating the gas above the space above the storage container with the gas supply port, A filling stopping means for bringing the space above the storage container into communication with the inside of the chamber to achieve a pressure equilibrium state, and a pressure releasing means for connecting the space in the chamber and above the storage container with the gas supply port are provided. And
In the liquid material filling device, preferably, a switching valve for switching between a first position for communicating the chamber communication pipe and the negative pressure supply source and a second position for communicating the chamber communication pipe and the gas supply port is further provided. And the control device sets the switching valve to the first position in the decompression means, and sets the switching valve to the second position in the pressure release means, and more preferably further includes a chamber. A first flow control valve provided in a flow path that communicates the communication pipe and the gas supply port; and a second flow control valve provided in a flow path that communicates the discharge apparatus communication pipe and the gas supply port. More preferably, the maximum flow rate of the first flow control valve is set to be three times or more the maximum flow rate of the second flow control valve.
The liquid material filling device may further include a sensor that transmits a liquid detection signal to the control device.
上記液体材料充填方法において、前記減圧工程において、流量制御弁を経時的に調節して、チャンバーおよび貯留容器内のエアを緩やかに排出することを特徴としてもよい。
上記液体材料充填方法において、前記充填工程において、流量制御弁を経時的に調節しながら貯留容器内の上方にある空間へ緩やかにガスを流入すること、並びに、前記圧力開放工程において、流量制御弁を経時的に調節しながら貯留容器内の上方にある空間へ緩やかにガスを流入することを特徴としてもよく、ここで好ましくは、前記圧力開放工程において、前記流量制御弁の最大流量が、前記充填工程における流量制御弁の最大流量の3倍以上に設定されることを特徴とする。
上記液体材料充填方法において、前記吐出装置が、吐出口と連通する液室内でロッドが動作する吐出装置であることを特徴としてもよい。 The liquid material filling method of the present invention is a method of filling an internal flow path of a discharge device installed in a chamber with a liquid material, wherein the discharge device includes an outlet communicated with a discharge port and a pipe to which negative pressure is supplied. Including a liquid storage container with a connected connector, decompressing the space in the chamber and above the storage container to a vacuum or a low pressure close to vacuum, reducing the space in the chamber and above the storage container for a certain period of time A degassing step for degassing bubbles in the liquid material while maintaining the pressure state, and the space above the storage container is connected to the gas supply port so that the gas flows in to a higher pressure than in the chamber. The filling process of filling the liquid material in the discharge device, after detecting that the liquid droplet flows out from the discharge port, the space above the storage container is immediately communicated with the inside of the chamber to be in a pressure equilibrium state, Filling stopping step of stopping the filling of the body material, and characterized by having a pressure release step of the space above the chamber and the reservoir in communication with the gas supply port flows of gas.
The liquid material filling method may be characterized in that, in the decompression step, the air in the chamber and the storage container is gently discharged by adjusting the flow rate control valve over time.
In the liquid material filling method, in the filling step, the gas is gently introduced into the space above the storage container while adjusting the flow rate control valve over time, and in the pressure release step, the flow rate control valve The gas may gradually flow into the space above the storage container while adjusting the time, and preferably, in the pressure release step, the maximum flow rate of the flow control valve is It is characterized by being set to 3 times or more of the maximum flow rate of the flow rate control valve in the filling step.
In the liquid material filling method, the discharge device may be a discharge device in which a rod operates in a liquid chamber communicating with a discharge port.
本発明の液体材料充填装置1は、図1に示すように、チャンバー10と、圧力調節部70と、制御装置100とを主要な構成要素とする。気密構造のチャンバー10の中に吐出装置50が設置され、充填工程が実施される。圧力調節部70は、チャンバー10および吐出装置50の貯留容器51の圧力を調節するものであり、制御装置100により動作が制御される。 <Configuration>
As shown in FIG. 1, the liquid material filling apparatus 1 of the present invention includes a
扉11の開閉は把手12を掴んで行われる。扉11を閉めて額縁状に設けられた気密部材15を押圧した状態で、係止具A13および係止具B14により扉11を固定することでチャンバー内を気密にできる。チャンバー10の上部の直方体状の筐体内には、制御装置100および圧力調節部70が設置されている。この筐体の正面には、負圧計A87および負圧計B88が配置されており、正面から視認することができる。 As shown in FIG. 2, the
The
負圧供給源71は、所定の負圧を供給するもので、例えば真空ポンプに減圧弁を組み合わせて構成することができる。
切換弁86は、負圧供給源71と開閉弁A83とを連通する第1位置と、開閉弁A83とガス供給口92とを流量制御弁C82を介して連通する第2位置とを切り換える。
チャンバー10に挿通される管A90の一端は、チャンバー内空間に開放されている。チャンバー10に挿通される管B91の一端は、貯留容器51の下端出口と連通している。管A90および管B91は、図1に示す如く、流量制御弁80~82、開閉弁83~85および切換弁86を介してガス供給口92,93および負圧源71と連通している。なお、本実施形態例では、ガス供給口を大気と連通させ大気ガスを供給しているが、ガス供給口を不活性ガス供給源と連通させ不活性ガスを供給するようにしてもよい。 The
The negative
The
One end of the pipe A90 inserted through the
貯留容器51と吐出装置本体52は、内部に流路が設けられた液送部材56を介して連結されている。吐出装置本体52の一方の側面には、電磁弁57が固設されている。
吐出口53と連通する液室54内には、鉛直方向に延伸するロッド55の先端が配置されている。ロッド55は、例えばピエゾ素子からなるロッド駆動源により、液室54内を往復移動する。
貯留容器51は、下端に出口を有し、上端に開口を有している。貯留容器51の開口を覆う蓋部材(コネクタ)にはエアチューブが接続され、エア圧力供給58のエア供給口と連通される。コントローラ59は、電磁弁57およびエア圧力供給58の動作を制御する。
吐出装置50をチャンバー10内に設置する際は、エア圧力供給58およびコントローラ59との接続は外される。この際、ロッド55は上昇位置で固定し、ロッド55が液室54と吐出口53とを連通する流路を塞がないようにする。すなわち、チャンバー10内には、吐出口53と液体貯留容器51の出口とが連通する状態の吐出装置50を設置する。 FIG. 4 is a cross-sectional side view of an essential part showing the configuration of the
The
In the
The
When the
図4に示した吐出装置50は一例に過ぎず、吐出口と連通する液室内でロッドが動作するあらゆる吐出装置に本発明は適用可能である。例えば、ノズルに連通する流路の端部に設けられた弁座に弁体を衝突させてまたは弁体を弁座に衝突する寸前に停止させて液体材料をノズル先端より飛翔吐出させるジェット式の吐出装置、先端にノズルを有する貯留容器の内面に密着摺動するプランジャーを所望量移動して吐出するプランジャー式、スクリューの回転により液体材料を吐出するスクリュー式の吐出装置にも本発明は適用可能である。 The
The
(準備工程:吐出装置の取り付け等)
作業者は、準備工程として次の作業を行う。
(1)チャンバー10内にあるホルダー60に吐出装置50を取り付ける。
(2)液体材料を貯留する貯留容器51の開口を覆う蓋部材に管B91を接続し、貯留容器51内の上方に閉空間を作る。
(3)吐出装置50の吐出口53の下に受け皿62を設置する。
(4)吐出装置50の吐出口53から下方に延びる垂直線と、液滴検知センサ61の検知範囲が重なるようにする。 <Filling process>
(Preparation process: installation of the discharge device, etc.)
The worker performs the following work as a preparation process.
(1) The
(2) The tube B91 is connected to a lid member that covers the opening of the
(3) A
(4) The vertical line extending downward from the
制御装置100が、切換弁86を負圧供給源71と開閉弁A83とを連通する第1位置とし、開閉弁A83および開閉弁B84を開き、開閉弁C85を閉じた状態とする。この状態では、負圧供給源71は管A90を介してチャンバー10と連通し、管B91を介して貯留容器51と連通している。そのため、負圧供給源71からの負圧によりチャンバー10内の圧力および貯留容器51内の上方に存在する気体の圧力は減少する。
吐出装置50の吐出口53はチャンバー内空間に開放されているので、吐出口53と連通する装置本体52の内部流路は、チャンバー10の圧力減少に伴い減圧される。この際、制御装置100により流量制御弁A80を経時的に調節して、チャンバー10および貯留容器51内の空気が急激に排気されないようコントロールすることが好ましい。吐出装置50内の流路および貯留容器51内に急激な圧力変化が生じると気泡混入のおそれがあり、特に貯留容器51内の液体材料が暴れてしまうと気泡を混入するおそれが相当程度高まるからである。 (First step: Depressurization of chamber and storage container)
The
Since the
制御装置100は、負圧計A87と負圧計B88が所望の圧力(すなわち、真空または真空に近い低圧力)に到達したら、開閉弁A83を閉じる。これにより、負圧供給源71からチャンバー10および貯留容器51への負圧の供給が停止し、チャンバー10内の圧力と貯留容器51内の圧力および装置本体52の内部流路の圧力が等しい状態となる。この状態においては、装置本体52の内部流路は実質的に真空となり、チャンバー10内に存在する全ての液体材料から気泡が除去される。気泡を除去する工程は、予め設定した一定時間継続して行われる。 (Second step: removal of bubbles)
When the negative pressure gauge A87 and the negative pressure gauge B88 reach a desired pressure (that is, vacuum or a low pressure close to vacuum), the
制御装置100は、一定時間経過後開閉弁B84を閉じ、管A90と管B91の連通を遮断する。これにより、チャンバー10と貯留容器51の上方の空間との連通が遮断される。続いて、制御装置100は、流量制御弁B81を閉じてから、開閉弁C85を開く。この際、流量制御弁B81は閉じているので、負圧計B88の指示値は変化しない。
続いて、制御装置100は、流量制御弁B81を徐々に開く。これにより、ガス供給口93から開閉弁C85を介して貯留容器51の上方の空間内に大気ガスが流入する。この際、貯留容器50内の液体材料が急激に装置本体52の内部流路に流れ込まないように、制御装置100により流量制御弁B81の開放度合いを調節することが好ましい。 (Third step: start filling liquid material)
The
Subsequently, the
なお、上記では、制御装置100により開閉弁C85を開いた後に流量制御弁B81を開く方法を説明したが、制御装置100により予め流量制御弁B81の開き度合いを設定してから開閉弁C85を開いても良い。 As the amount of atmospheric gas flowing into the
In the above description, the method of opening the flow control valve B81 after the
負圧計B88の指示値が所望値に到達したら、制御装置100は開閉弁C85を閉じる。負圧計B88の指示値に代わり、一定時間経過後に開閉弁C85を閉じるのでもよい。この際、開閉弁B84を閉じたままとすることにより、負圧計A87と負圧計B88の差圧が維持される。従って、液体材料は貯留容器から51から装置本体52の内部流路へ緩やかに流れ続ける。液滴検知センサ61からの検出信号により貯留容器51から流入した液体材料が吐出口53まで到達したことが確認されたら、制御装置100は開閉弁B84を開き、管A90と管B91を連通する。これにより、貯留容器51内の圧力とチャンバー10との圧力差がなくなり、貯留容器51から装置本体52の内部流路への液体材料の流入が停止する。このとき、負圧計A87と負圧計B88の指示値は等しくなっている(圧力平衡状態)。 (Fourth step: Stop filling liquid material)
When the indicated value of the negative pressure gauge B88 reaches a desired value, the
制御装置100は切換弁86を第2位置に設定し、開閉弁A83と流量制御弁C82とを連通させる。この際、開閉弁A83および流量制御弁C82は閉じた状態にあり、開閉弁B84は開いた状態にある。続いて、制御装置100は開閉弁A83を開き、流量制御弁C82を徐々に開く。これにより、ガス供給口92から大気ガスが、管A90を介してチャンバー10に流入し、管B91を介して貯留容器51の上方空間内に流入する。チャンバー10および貯留容器51の圧力が上昇し、大気圧と等しくなる。
なお、上記では、制御装置100により開閉弁A83を開いた後に流量制御弁C82を開く方法を説明したが、制御装置100により流量制御弁C82の開き度合いを設定してから開閉弁A83を開いても良い。 (5th step: Release of negative pressure in the chamber)
The
In the above description, the method of opening the flow control valve C82 after the
但し、第3の工程における貯留容器51への大気ガスの流入と第5の工程における大気ガスの流入を比べると、後者の方が著しく流入量が多いため、大気ガスの流入口を分けた方が良い場合がある。すなわち、切換弁86を設けた構成の方が、ガス供給口92からは大流量の弁を介して大気ガスを流入させ、ガス供給口93からは小流量の弁を介して大気ガスを流入させることができるので、第5の工程において速やかにチャンバー内の負圧を開放することが可能となる。例えば、流量制御弁C82の最大流量を流量制御弁B81の3倍以上(好ましくは5倍以上、より好ましくは10倍以上)とすることも可能である。 Furthermore, in this step, atmospheric gas may flow into the upper space of the
However, comparing the inflow of atmospheric gas into the
作業者は、負圧計A87および負圧計B88の指示値が大気圧に戻ったことを目視確認し、チャンバー10から吐出装置50(貯留容器51および装置本体52)を取り出す。
以上に説明した第1~5の工程は自動で行われるのが原則であるが、その一部または全部を人手により行うことも当然に可能である。 (Post-process: ejection device removal)
The operator visually confirms that the indicated values of the negative pressure gauge A87 and the negative pressure gauge B88 have returned to atmospheric pressure, and takes out the discharge device 50 (the
In principle, the first to fifth steps described above are performed automatically, but it is naturally possible to perform part or all of them manually.
本発明によれば、貯留容器から吐出口に至る流路内に気泡が残留しないので、吐出量が安定し、吐出不良が生じないという有利な効果が奏される。また、残留気泡を原因とする吐出口からの液だれ、後だれがなくなるので、クリーンに吐出できる。さらには、吐出口から液滴の状態で吐出を行う吐出装置においては、着弾位置の精度が上がる。本発明は、特に吐出口と連通する液室内に作業軸(ロッド)の先端部分が配置されるメカ式吐出装置に大変有効である。 According to the liquid material filling apparatus 1 described above, since the liquid material is filled in a vacuum state in which the atmosphere does not remain or in a substantially vacuum state, the liquid material filling device 1 remains in every corner of the flow path from the storage container to the discharge port. Liquid material without bubbles spreads. Further, since the discharge device itself is in a vacuum state in the chamber, there is no possibility that gas flows from the discharge port into the internal flow path of the discharge device.
According to the present invention, since bubbles do not remain in the flow path from the storage container to the discharge port, an advantageous effect is achieved that the discharge amount is stable and discharge failure does not occur. Further, since there is no liquid dripping or no dripping from the discharge port due to residual bubbles, the liquid can be discharged cleanly. Furthermore, in an ejection device that ejects liquid droplets from the ejection port, the accuracy of the landing position is improved. The present invention is particularly effective for a mechanical discharge device in which a tip end portion of a work shaft (rod) is disposed in a liquid chamber communicating with a discharge port.
10:チャンバー
11:扉
12:把手
13:係止具A
14:係止具B
15:シール部材
50:吐出装置
51:貯留容器(シリンジ)
52:装置本体
53:吐出口
54:液室
55:ロッド
56:液送部材
57:電磁弁
58:エア圧力供給
59:コントローラ
60:ホルダー
61:液滴検知センサ
62:受け皿
70:圧力調節部
71:負圧供給源
80:流量制御弁A
81:流量制御弁B
82:流量制御弁C
83:開閉弁A
84:開閉弁B
85:開閉弁C
86:切換弁
87:負圧計A(圧力計A)
88:負圧計B(圧力計B)
90:管A(チャンバー連通管)
91:管B(吐出装置連通管)
92:ガス供給口
93:ガス供給口
100:制御装置 1: Liquid material filling apparatus 10: Chamber 11: Door 12: Handle 13: Locking tool A
14: Locking tool B
15: Seal member 50: Discharge device 51: Storage container (syringe)
52: apparatus main body 53: discharge port 54: liquid chamber 55: rod 56: liquid feeding member 57: electromagnetic valve 58: air pressure supply 59: controller 60: holder 61: droplet detection sensor 62: tray 70: pressure adjusting unit 71 : Negative pressure supply source 80: Flow control valve A
81: Flow control valve B
82: Flow control valve C
83: On-off valve A
84: On-off valve B
85: On-off valve C
86: Switching valve 87: Negative pressure gauge A (pressure gauge A)
88: Negative pressure gauge B (pressure gauge B)
90: Tube A (chamber communication tube)
91: Pipe B (Discharge device communication pipe)
92: Gas supply port 93: Gas supply port 100: Control device
Claims (12)
- 気密構造のチャンバーと、チャンバー内の圧力を調節する圧力調節部と、制御装置と、を備え、吐出装置の内部流路に液体材料を充填する液体材料充填装置において、
前記吐出装置が、吐出口と連通された出口およびコネクタを有する液体貯留容器を含み、
前記圧力調節部が、負圧供給源と、チャンバーと連通するチャンバー連通管と、前記液体貯留容器のコネクタと連通される吐出装置連通管と、チャンバー連通管とガス供給口とを連通または遮断する開閉弁Aと、チャンバー連通管と吐出装置連通管とを連通または遮断する開閉弁Bと、吐出装置連通管とガス供給口とを連通または遮断する開閉弁Cと、圧力計と、を有し、
制御装置が、負圧供給源とチャンバー連通管および吐出装置連通管を連通してチャンバー内および貯留容器の上方にある空間を真空または真空に近い低圧力に減圧する減圧手段、
チャンバー内および貯留容器の上方にある空間を一定時間低圧力の状態に維持して液体材料内の気泡を脱気する脱気手段、
貯留容器の上方にある空間をガス供給口と連通してガスを流入することでチャンバー内よりも高圧として貯留容器内の液体材料を吐出装置に充填する充填手段、
貯留容器の上方にある空間をチャンバー内と連通して圧力平衡状態とする充填停止手段、並びに、
チャンバー内および貯留容器の上方にある空間をガス供給口と連通する圧力開放手段を備えることを特徴とする液体材料充填装置。 In a liquid material filling apparatus that includes a chamber having an airtight structure, a pressure adjustment unit that regulates the pressure in the chamber, and a control device, and fills the internal flow path of the discharge device with a liquid material
The discharge device includes a liquid storage container having an outlet and a connector communicated with the discharge port,
The pressure adjusting unit communicates or blocks a negative pressure supply source, a chamber communication pipe communicating with the chamber, a discharge device communication pipe communicating with the connector of the liquid storage container, and the chamber communication pipe and the gas supply port. An on-off valve A, an on-off valve B for communicating or blocking the chamber communication tube and the discharge device communication tube, an on-off valve C for connecting or blocking the discharge device communication tube and the gas supply port, and a pressure gauge ,
A pressure reducing means for reducing the space in the chamber and above the storage container to a vacuum or a low pressure close to a vacuum by connecting the negative pressure supply source, the chamber communication tube, and the discharge device communication tube;
A degassing means for degassing bubbles in the liquid material by maintaining the space in the chamber and above the storage container at a low pressure for a certain period of time;
A filling means for filling the discharge device with the liquid material in the storage container at a higher pressure than in the chamber by communicating the gas above the space above the storage container with the gas supply port;
A filling stop means for communicating the space above the storage container with the inside of the chamber to achieve a pressure equilibrium state, and
A liquid material filling apparatus comprising pressure release means for communicating a space in a chamber and above a storage container with a gas supply port. - さらに、チャンバー連通管と負圧供給源とを連通する第1の位置およびチャンバー連通管とガス供給口とを連通する第2の位置を切り換える切換弁とを備え、
前記制御装置が、前記減圧手段において切換弁を第1の位置とすること、並びに、前記圧力開放手段において切換弁を第2の位置とすることを特徴とする請求項1に記載の液体材料充填装置。 And a switching valve for switching between a first position for communicating the chamber communication pipe and the negative pressure supply source and a second position for communicating the chamber communication pipe and the gas supply port,
2. The liquid material filling according to claim 1, wherein the control device sets the switching valve to a first position in the pressure-reducing means, and sets the switching valve to a second position in the pressure release means. apparatus. - さらに、チャンバー連通管とガス供給口とを連通する流路に設けられた第1の流量制御弁と、吐出装置連通管とガス供給口とを連通する流路に設けられた第2の流量制御弁とを備えることを特徴とする請求項2に記載の液体材料充填装置。 Further, a first flow rate control valve provided in a flow path that connects the chamber communication pipe and the gas supply port, and a second flow rate control provided in a flow path that connects the discharge device communication pipe and the gas supply port. The liquid material filling device according to claim 2, further comprising a valve.
- 第1の流量制御弁の最大流量が、第2の流量制御弁の最大流量の3倍以上に設定されることを特徴とする請求項3に記載の液体材料充填装置。 4. The liquid material filling device according to claim 3, wherein the maximum flow rate of the first flow rate control valve is set to three times or more of the maximum flow rate of the second flow rate control valve.
- さらに、前記制御装置に液体検出信号を送信するセンサを備えることを特徴とする請求項1ないし4のいずれかに記載の液体材料充填装置。 The liquid material filling device according to claim 1, further comprising a sensor that transmits a liquid detection signal to the control device.
- チャンバーに設置された吐出装置の内部流路に液体材料を充填する方法において、
前記吐出装置が、吐出口と連通された出口および負圧が供給される管が接続されたコネクタを有する液体貯留容器を含み、
チャンバー内および貯留容器の上方にある空間を真空または真空に近い低圧力に減圧する減圧工程、
チャンバー内および貯留容器の上方にある空間を一定時間低圧力の状態に維持して液体材料内の気泡を脱気する脱気工程、
貯留容器の上方にある空間をガス供給口と連通してガスを流入することでチャンバー内よりも高圧とし、貯留容器内の液体材料を吐出装置に充填する充填工程、
吐出口から液滴が流出するのを検出後、速やかに貯留容器の上方にある空間をチャンバー内と連通して圧力平衡状態とし、液体材料の充填を停止する充填停止工程、並びに、
チャンバー内および貯留容器の上方にある空間をガス供給口と連通してガスを流入する圧力開放工程を有する液体材料充填方法。 In the method of filling the liquid material into the internal flow path of the discharge device installed in the chamber,
The discharge device includes a liquid storage container having a connector connected to an outlet connected to the discharge port and a pipe to which negative pressure is supplied,
Depressurization step for reducing the space in the chamber and above the storage container to a vacuum or a low pressure close to vacuum,
A degassing step of degassing bubbles in the liquid material by maintaining the space in the chamber and above the storage container at a low pressure for a certain period of time;
A filling step of filling the discharge device with the liquid material in the storage container by making the space above the storage container communicate with the gas supply port so that the gas flows in and making the pressure higher than in the chamber;
After detecting that the liquid droplet flows out from the discharge port, a filling stop step for quickly filling the space above the storage container with the inside of the chamber to be in a pressure equilibrium state, and stopping filling of the liquid material, and
A liquid material filling method including a pressure release step of allowing gas to flow through a space in the chamber and above the storage container and communicating with a gas supply port. - 前記減圧工程において、流量制御弁を経時的に調節して、チャンバーおよび貯留容器内のエアを緩やかに排出することを特徴とする請求項6に記載の液体材料充填方法。 The liquid material filling method according to claim 6, wherein, in the decompression step, the air in the chamber and the storage container is gently discharged by adjusting a flow rate control valve over time.
- 前記充填工程において、流量制御弁を経時的に調節しながら貯留容器内の上方にある空間へ緩やかにガスを流入すること、並びに、
前記圧力開放工程において、流量制御弁を経時的に調節しながら貯留容器内の上方にある空間へ緩やかにガスを流入することを特徴とする請求項6または7に記載の液体材料充填方法。 In the filling step, slowly flowing gas into the space above the storage container while adjusting the flow rate control valve over time; and
8. The liquid material filling method according to claim 6, wherein in the pressure releasing step, gas is gently introduced into a space above the inside of the storage container while adjusting a flow rate control valve over time. - 前記圧力開放工程において、前記流量制御弁の最大流量が、前記充填工程における流量制御弁の最大流量の3倍以上に設定されることを特徴とする請求項8に記載の液体材料充填方法。 The liquid material filling method according to claim 8, wherein, in the pressure release step, the maximum flow rate of the flow rate control valve is set to three times or more of the maximum flow rate of the flow rate control valve in the filling step.
- 前記吐出装置が、吐出口と連通する液室内でロッドが動作する吐出装置であることを特徴とする請求項6または7に記載の液体材料充填方法。 The liquid material filling method according to claim 6 or 7, wherein the discharge device is a discharge device in which a rod operates in a liquid chamber communicating with a discharge port.
- 前記吐出装置が、吐出口と連通する液室内でロッドが動作する吐出装置であることを特徴とする請求項8に記載の液体材料充填方法。 The liquid material filling method according to claim 8, wherein the discharge device is a discharge device in which a rod operates in a liquid chamber communicating with a discharge port.
- 前記吐出装置が、吐出口と連通する液室内でロッドが動作する吐出装置であることを特徴とする請求項9に記載の液体材料充填方法。 10. The liquid material filling method according to claim 9, wherein the discharge device is a discharge device in which a rod operates in a liquid chamber communicating with a discharge port.
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PL14850194T PL3053660T3 (en) | 2013-10-05 | 2014-10-03 | Method and device for filling of liquid material |
EP14850194.3A EP3053660B1 (en) | 2013-10-05 | 2014-10-03 | Method and device for filling of liquid material |
CN201480054619.9A CN105592937B (en) | 2013-10-05 | 2014-10-03 | Fluent material filling device and method |
KR1020167006144A KR102288108B1 (en) | 2013-10-05 | 2014-10-03 | Method and device for filling of liquid material |
HK16109550.5A HK1221434A1 (en) | 2013-10-05 | 2016-08-10 | Method and device for filling of liquid material |
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